Interleaved parallel circuit, integrated power module and integrated power chip

ABSTRACT

The present disclosure provides an interleaved parallel circuit, an integrated power module and an integrated power chip. The interleaved parallel circuit includes a first bridge arm and a second bridge arm at least partly formed in a wafer containing a plurality of first cell groups and a plurality of second cell groups. The plurality of first cell groups are configured to form the first upper bridge-arm switch and the plurality of second cell groups are configured to form the second upper bridge-arm switch, or the plurality of first cell groups are configured to form the first lower bridge-arm switch and the plurality of second cell groups are configured to form the second lower bridge-arm switch. The plurality of first cell groups and the plurality of second cell groups are switched on and off in an interleaved mode.

CROSS REFERENCE

This application is based upon and claims priority to Chinese Patent Application No. 201610783952.4, filed on Aug. 31, 2016, the entire contents thereof are incorporated herein by reference.

TECHNICAL FIELD

The present disclosure relates to electrical and electronic technology, and more particularly, to an interleaved parallel circuit, an integrated power module and an integrated power chip.

BACKGROUND

Power semiconductor devices are core components of energy conversion and system power supply equipment. The performances of the power semiconductor devices directly affect the overall efficiency of the industrial applications, especially for power supply configurations of processors, communication systems and data centers in a large number of electronic products. In all kinds of power supply circuits for processors, in order to meet the requirement of a long system running time, it poses a great challenge to the entire circuit in terms of efficiency and power consumption. On the other hand, high power consumption also means temperature rise and waste of power, which threatens reliable operation of the processor system in a long run, and causes additional cost for heat dissipation for the circuit.

Presently, in power supply circuit of a server system, a data center or other types of processors, the rapid improvement of the performance of the core processor and the enhanced integration of the core processor impose high requirements on the power density and efficiency of the power supply. In such power supply circuits, since the supply voltage is low for the load such as the processor, there is a high conduction loss for the circuit which operates under a low voltage and a large current for a long time. In this case, the conduction loss includes not only the loss on the power devices, but also the loss on the metal connection in the circuit system. Accordingly, there is a demand for reducing the conduction loss in design of the devices and the circuits.

As shown in FIG. 1 is a conventional topology of a power source, which includes a power switch Q1, a power switch Q2, an input power V_(IN), an inductor L and a filtering capacitor C_(o). An ideal power chip does not have any stray parameters. While in practice, the power chip has package stray parameters Z1 and Z2 generated by an interconnect metal layer (RDL), an external pin, a package interconnection, a system board interconnection. When there is a large current flowing in the circuit, the conduction loss will be generated on Q1 and Q2 as well as on the stray parameters Z1 and Z2. With the supply voltage of the load being decreased, the voltage levels of the power devices Q1 and Q2 in the circuit are decreased, and the conduction performance of the power devices is improved, while the stay parameters Z1 and Z2 due to all of the wires and metal connections in the circuit bring an increasingly high proportion of conduction loss.

For example, for a typical 15V power device, a conduction impedance of a metal layer of the device is up to 20% of the entire impedance. In order to improve power density and efficiency, how to reduce conduction loss of other parts than the semiconductor itself and how to fully utilize the interconnect conduction path (including a metal interconnection layer inside the chip, package connection, pins and metal connection of the system board) becomes an important topic.

In order to reduce conduction loss, a highly efficient optimization method is to take full utilization of all the metal connection resources, and make current flowing evenly in time domain. As shown in FIG. 2(a) is a typical circuit in which the conduction paths are conducted in a discontinuous way, delivering power cycle by cycle. In contrast. FIG. 2(b) shows ideal evenly conducted current in which power is transferred continuously through the circuit. Although the power transferred through the two circuits is of the same amount, the conduction loss in the discontinuous conduction mode of FIG. 2(a) is significantly higher than the continuous mode in FIG. 2(b).

Therefore, there is a demand for a novel interleaved parallel circuit, a novel integrated power module and a novel integrated power chip.

The above information disclosed in the BACKGROUND is merely for better understanding of the context of the present disclosure, and may include contents that do not constitute the known prior art of those skilled in the art.

SUMMARY

The present disclosure provides an interleaved parallel circuit, an integrated power module and an integrated power chip, which are capable of reducing loss of the metal layers of the power device by integrating the chip, reducing the overall loss of the power supply circuit and improving the system efficiency.

The other characteristics and advantages of the present disclosure may become apparent from the following detailed description, or partly learned from the practice of the present disclosure.

According to one aspect of the present disclosure, there is provided an interleaved parallel circuit including a first bridge arm and a second bridge arm, wherein the first bridge arm includes: a first upper bridge-arm switch including a first terminal, a second terminal and a control terminal; and a first lower bridge-arm switch including a first terminal, a second terminal and a control terminal; wherein the second terminal of the first upper bridge-arm switch is electrically connected to the first terminal of the first lower bridge-arm switch; the second bridge arm includes: a second upper bridge-arm switch including a first terminal, a second terminal and a control terminal; and a second lower bridge-arm switch including a first terminal, a second terminal and a control terminal; wherein the second terminal of the second upper bridge-arm switch is electrically connected to the first terminal of the second lower bridge-arm switch; wherein the first bridge arm and the second bridge arm are at least partly formed in a wafer containing a plurality of first cell groups and a plurality of second cell groups; wherein the plurality of first cell groups are configured to form the first upper bridge-arm switch of the first bridge arm and the plurality of second cell groups are configured to form the second upper bridge-arm switch of the second bridge arm, or the plurality of first cell groups are configured to form the first lower bridge-arm switch of the first bridge arm and the plurality of second cell groups are configured to form the second lower bridge-arm switch of the second bridge arm; and the plurality of first cell groups and the plurality of second cell groups are switched on and off in an interleaved mode.

According to an aspect of the present disclosure, there is provided an integrated power module, which is applied in an interleaved parallel circuit, including a first bridge arm and a second bridge arm, wherein the first bridge arm includes: a first upper bridge-arm switch including a first terminal, a second terminal and a control terminal; and a first lower bridge-arm switch including a first terminal, a second terminal and a control terminal; a first electrode electrically connected to the first terminal of the first upper bridge-arm switch; a second electrode electrically connected to the second terminal of the first lower bridge-arm switch; and a third electrode electrically connected to the second terminal of the first upper bridge-arm switch and the first terminal of the first lower bridge-arm switch; the second bridge arm includes: a second upper bridge-arm switch including a first terminal, a second terminal and a control terminal, the first electrode being electrically connected to the first terminal of the second upper bridge-arm switch; a second lower bridge-arm switch including a first terminal, a second terminal and a control terminal, the second electrode being electrically connected to the second terminal of the second lower bridge-arm switch; and a fourth electrode electrically connected to the second terminal of the second upper bridge-arm switch and the first terminal of the second lower bridge-arm switch; the integrated power module further includes: a first inductor including a first terminal and a second terminal, the first terminal of the first inductor being electrically connected to the third electrode; and a second inductor including a first terminal and a second terminal, the first terminal of the second inductor being electrically connected to the fourth electrode; wherein the second terminal of the first inductor is electrically connected to the second terminal of the second inductor; the first upper bridge-arm switch of the first bridge arm and the second upper bridge-arm switch of the second bridge arm and/or the first lower bridge-arm switch of the first bridge arm and the second lower bridge-arm switch of the second bridge arm are formed in a wafer.

According to an aspect of the present disclosure, there is provided an integrated power chip, which is applied in a power circuit including a first bridge arm and a second bridge arm, the first bridge arm including a first upper bridge-arm switch and a first lower bridge-arm switch, the second bridge arm including a second upper bridge-arm switch and a second lower bridge-arm switch, wherein the integrated power chip includes a first switch and a second switch, the first switch and second switch are formed in a wafer, and the wafer contains a plurality of first cell groups and a plurality of second cell groups; wherein the plurality of first cell groups are configured to form the first switch as the first upper bridge-arm switch of the first bridge arm, the plurality of second cell groups are configured to form the second switch as the second upper bridge-arm switch of the second bridge arm, or the plurality of first cell groups are configured to form the first switch as the first lower bridge-arm switch of the first bridge arm, the plurality of second cell groups are configured to form the second switch as the second lower bridge-arm switch of the second bridge arm; and the plurality of first cell groups and the plurality of second cell groups are switched on and off in an interleaved mode.

Accordingly, the technical solution of the present disclosure may have advantages and beneficial effects compared with the related art. Specifically, through the present disclosure, the upper bridge-arm switches and/or lower bridge-arm switches of the bridge arms may be formed in the same wafer. Cells of the groups on the wafer are disposed in parallel and switched on in successive phases so that current may be conducted evenly in time domain. Thereby, the conduction loss on the metal interconnection layer inside the chip can be reduced and the overall efficiency of the power supply system can be improved.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments consistent with the present disclosure and, together with the description, serve to explain the principles of the present disclosure.

FIG. 1 schematically illustrates an existing power supply topology;

FIG. 2(a) schematically illustrates a time sequence chart of current conduction in the switch circuit as shown in FIG. 1:

FIG. 2(b) illustrates an ideal time sequence chart of evenly conducted current;

FIG. 3 schematically illustrates a circuit diagram based on theory analysis of the circuit as shown in FIG. 1;

FIG. 4 schematically illustrates a circuit diagram of an interleaved parallel circuit according to a first exemplary embodiment of the present disclosure;

FIG. 5 schematically illustrates a circuit diagram of an interleaved parallel circuit according to a second exemplary embodiment of the present disclosure;

FIG. 6 schematically illustrates a circuit diagram of an interleaved parallel circuit according to a third exemplary embodiment of the present disclosure;

FIG. 7(a) schematically illustrates a time sequence chart of current conduction of the power chip as shown in FIG. 3;

FIG. 7(b) schematically illustrates a time sequence chart of current conduction of the interleaved parallel circuit as shown in FIG. 4;

FIG. 8(a) schematically illustrates a time sequence chart of current conduction of the input side of the power chip as shown in FIG. 3;

FIG. 8(b) schematically illustrates a time sequence chart of current conduction of the input side of the interleaved parallel circuit as shown in FIG. 4;

FIG. 9(a) schematically illustrates two cell groups switched on simultaneously inside a power chip operated in the same phase;

FIG. 9(b) schematically illustrates two cell groups switched off simultaneously inside a power chip operated in the same phase;

FIGS. 10(a) and 10(b) respectively schematically illustrate two cell groups switched on and off successively inside a power chip operated in successive phases;

FIGS. 11(a) and 11(b) respectively schematically illustrate cell groups switched on and off successively, with an external pin disposed near an edge position of a power chip operated in successive phases;

FIGS. 12(a) and 12(b) respectively schematically illustrate cell groups switched on and off successively, with an external pin disposed near a central position of a power chip operated in successive phases;

FIGS. 13(a) and 13(b) respectively schematically illustrate cell groups switched on and off successively, with the cell groups arranged alternatively and an external pin disposed near an edge position of a power chip operated in successive phases;

FIGS. 14(a) and 14(b) respectively schematically illustrate cell groups switched on and off successively, with the cell groups arranged alternatively and an external pin disposed near a central position of a power chip operated in successive phases;

FIG. 15 schematically illustrates an external pin disposed near an edge position of a power chip inside a power chip operated in the same phase;

FIG. 16 schematically illustrates an external pin disposed near a central position of a power chip inside a power chip operated in the same phase;

FIG. 17 schematically illustrates distribution of external pins of a power chip operated in successive phases as shown in FIG. 4;

FIG. 18 schematically illustrates another distribution of external pins of a power chip operated in successive phases as shown in FIG. 4;

FIG. 19 schematically illustrates a first distribution of external pins of a power chip operated in successive phases as shown in FIG. 6;

FIG. 20 schematically illustrates a second distribution of external pins of a power chip operated in successive phases as shown in FIG. 6;

FIG. 21 schematically illustrates a third distribution of external pins of a power chip operated in successive phases as shown in FIG. 6;

FIG. 22 schematically illustrates two cell groups disposed in respective regions inside a power chip operated in successive phases;

FIG. 23 schematically illustrates two strip-shaped cell groups arranged alternatively and in parallel along a lateral direction inside a power chip operated in successive phases;

FIG. 24 schematically illustrates two polygon-shaped cell groups arranged alternatively inside a power chip operated in successive phases;

FIG. 25 schematically illustrates a BUCK circuit in which an interleaved parallel circuit according to the embodiments of the present disclosure is applied;

FIG. 26 schematically illustrates a BOOST circuit in which an interleaved parallel circuit according to the embodiments of the present disclosure is applied; and

FIG. 27 schematically illustrates a Totem-Pole circuit in which an interleaved parallel circuit according to the embodiments of the present disclosure is applied.

DETAILED DESCRIPTION

Now exemplary embodiments will be fully described with reference to accompanying drawings. However, the exemplary embodiments may be embodied in various forms, and should not be construed as limited to the examples set forth herein. Instead, the embodiments are provided to make the present disclosure more thorough and complete, and to convey the idea of the exemplary embodiments more fully to those skilled in the art. The accompanying drawings are only illustration of the present disclosure, and may be note drawn to scale. Same reference numbers throughout the drawings represent the same or similar parts, and redundant description thereof will be omitted.

In addition, the features, structures and characteristics described are combined in one or more embodiments in any suitable manner. In the description below, specific details are provided for fully understanding of the embodiments of the present disclosure. However, it should be appreciated by those skilled in the art that, one or more specific details may be omitted, or other method, device or steps may be employed in practice of the technical solution of the present disclosure. In other cases, known structure, method, device, implementation, material or operation will not be illustrated or described to avoid obscuring the aspects of the present disclosure.

The following exemplary embodiments do not represent all of the embodiments consistent with the present disclosure. Instead, they are merely examples of devices and methods that are consistent with some aspects of the present disclosure, as set forth in the appended claims.

In the embodiments and claims, the reference “couple” may generally refer to one component connected indirectly to another component through other components, or one component connected directly to another component without other components interposed in between.

In the embodiments and the scope of the application, an article word “a/an” and “the” may refer to one or more than one, unless specifically specified.

FIG. 3 schematically illustrates a circuit diagram based on theory analysis of FIG. 1.

In FIG. 3, the part in the dash-line box represents a power device such as a switch Q1 which may be divided into two cell groups S1 and S2. A first cell group S1 and a second cell group S2 form the switch Q1 of a single bridge arm in FIG. 1. A cell group S3 and a cell group S4 form the switch Q2 of a single bridge arm in FIG. 1. Actually, FIG. 3 shows only one bridge, as the point SW is represented. The two cell groups S1 and S2 are connected in parallel and switched on and off simultaneously. When the circuit is operated in a switch mode, the current of the system is as shown in FIG. 7(a). Since the first cell group S1 and the second cell group S2 in FIG. 3 are switched on and off simultaneously, the input current of the interleaved parallel circuit is a switch current with a peak value of 2i, as shown in FIG. 8(a).

If the separated devices are operated in successive phases, only the parts outside the power device such as connection metal on the system board may be fully utilized, and it cannot reduce conduction loss of metal inside the chip. Therefore, embodiments of the present disclosure provide a design of an interleaved parallel circuit inside the chip, in order to reduce conduction loss in the layers inside the chip and improve the efficiency of the entire power supply system.

FIG. 4 schematically illustrates a circuit diagram of an interleaved parallel circuit according to a first exemplary embodiment of the present disclosure.

As shown in FIG. 4, the interleaved parallel circuit 200 includes a first bridge arm and a second bridge arm. The first bridge arm includes a first upper bridge-arm switch Q1 and a first lower bridge-arm switch Q3. A second terminal 12 of the first upper bridge-arm switch Q1 is electrically connected to a first terminal 31 of the first lower bridge-arm switch Q3. The second bridge arm includes a second upper bridge-arm switch Q2 and a second lower bridge-arm switch Q4. A second terminal 22 of the second upper bridge-arm switch Q2 is electrically connected to a first terminal 41 of the second lower bridge-arm switch Q3.

In the exemplary embodiment, each of the switches Q1-Q4 may be a Metal-Oxide-Semiconductor Field-Effect Transistor (MOSFET). However, the present disclosure is not limited to the type of the device. Each of the switches may have a source electrode, a drain electrode and a gate electrode connected to a gate driver. The source electrode of the switch of the upper bridge-arm switch may be respectively connected to the drain electrode of the switch of the corresponding lower bridge-arm switch. The source electrode of the upper bridge-arm switch may also be respectively connected to a gate driver connected to the same upper bridge-arm switch. The source electrode of the first lower bridge-arm switch or the second lower bridge-arm switch may also be respectively connected to a gate driver connected to the same lower bridge-arm switch. It may be appreciated by those skilled in the art that the terms “upper” and “lower” used for describing the upper bridge-arm switches and the lower bridge-arm switches do not refer to actual and physical arrangement.

It should be noted that, although in the exemplary illustration in FIG. 4 and the exemplary description below, the circuit includes a first bridge arm and a second bridge arm connected in parallel, however, in practice, the interleaved parallel circuit may have a number n (n≧2) of interleaved parallel bridge arms, such as a third bridge arm, a fourth bridge arm, . . . and a n^(th) bridge arm. Each of the n bridge arms includes at least two bridge-arm switches, i.e. an upper bridge-arm switch and a lower bridge-arm switch.

In the first exemplary embodiment as shown in FIG. 4, the first bridge arm and the second bridge arm may be at least partly formed in a wafer. For example, the first upper bridge-arm switch Q1 of the first bridge arm and the second upper bridge-arm switch Q2 of the second bridge arm are formed in a wafer 20. The wafer 20 may be a power chip. If the circuit includes n parallel bridge arms, all of the upper bridge-arm switches of the n parallel bridge arms may be formed in the same wafer 20. Alternatively, any two, three or (n−1) of the upper bridge-arm switches of the n parallel bridge arms may be formed in the wafer 20. This is not limited in the present disclosure.

In the exemplary embodiment, the wafer 20 includes a plurality of first cell groups S1 and a plurality of second cell groups S2. Each of the first cell groups S1 and the second cell groups S2 may include one or more cells. The plurality of first cell groups S1 form the first upper bridge-arm switch Q1 of the first bridge arm, and the plurality of second cell groups S2 form the second upper bridge-arm switch Q2 of the second bridge arm. The plurality of first cell groups S1 and the plurality of second cell groups S2 may be independently operated in successive phases with a phase difference of 180 degrees, for example. The outlet terminals of the switches are respectively connected to a load inductor L1 and a load inductor L2. When the system is operated in a switch mode, the current in the operation mode is as shown in FIG. 7(b). When S1 and S2 are switched on, a discontinuous current with a duty cycle D and a peak value i flows through S1 and a discontinuous current with a duty cycle D and a peak value i flows through S2, respectively as shown in FIG. 4. Since S1 and S2 in FIG. 4 are operated in successive phases (for example with a phase difference of 180°), the current through S1 and S2 flows through the input side and the input-side current has a decreased peak value i, as shown in FIG. 8(b). In an embodiment, the wafer may have only a plurality of first cell groups and a plurality of second cell groups.

With a certain size of the wafer device itself, the cells inside the wafer may be grouped to form different upper bridge-arm switches, and the switches may be controlled in successive phases. In this way, when a power of the same level is transferred, the loss may be reduced.

The power chip semiconductor as shown in FIG. 3 has a conduction loss:

(2i)²×(Rdson/2)×D=2i ² Rdson×D  (1)

Where, Rdson is a conduction impedance of a switch, and D is a duty cycle of a current through the switch.

The power chip semiconductor operated in successive phases provided by the embodiments of the present disclosure as shown in FIG. 4 has a conduction loss:

((i)²×(Rdson)+(i)²×(Rdson))×D=2i ² Rdson×D  (2)

As can be seen from the above formulas (1) and (2), the power chip operated in the same phase and the power chip operated in successive phases has the same conduction loss on the semiconductors, but the input-side current of the power chip operated in successive phases may be more approximate to a desirable continuous conducted state.

In an interleaved parallel circuit 300 as shown in FIG. 5, the first bridge arm and the second bridge arm may be at least partly formed in a wafer. For example, the first lower bridge-arm switch Q3 of the first bridge arm and the second lower bridge-arm switch Q4 of the second bridge arm are formed in a wafer 30. Similarly, if the interleaved parallel circuit includes n parallel bridge arms, all of the lower bridge-arm switches of the n parallel bridge arms may be formed in the wafer 30. Alternatively, any two, three or (n−1) of the lower bridge-arm switches of the n parallel bridge arms may be formed in the wafer 30. This is not limited in the present disclosure. The wafer which forms the first lower bridge-arm switch Q3 and the second lower bridge-arm switch Q4 may be a different wafer from the wafer which forms the first upper bridge-arm switch Q1 and the second upper bridge-arm switch Q2, but the disclosure is not limited thereto.

In the exemplary embodiment, the wafer 30 includes a plurality of first cell groups S1 and a plurality of second cell groups S2. Each of the first cell groups S1 and the second cell groups S2 may include one or more cells. The plurality of first cell groups S1 form the first lower bridge-arm switch Q3 of the first bridge arm, and the plurality of second cell groups S2 form the second lower bridge-arm switch Q4 of the second bridge arm.

In an interleaved parallel circuit 400 as shown in FIG. 6, the first bridge arm and the second bridge arm may at least partly formed in a wafer. For example, the first upper bridge-arm switch Q1 and the first lower bridge-arm switch Q3 of the first bridge arm, and the second upper bridge-arm switch Q2 and the second lower bridge-arm switch Q4 of the second bridge arm are formed in a wafer 40. Similarly, if the interleaved parallel circuit includes n parallel bridge arms, all of the upper and lower bridge-arm switches of the n parallel bridge arms may be formed in the wafer 40. Alternatively, any two, three or (n−1) pairs of the upper and lower bridge-arm switches of the n parallel bridge arms may be formed in the wafer 40. This is not limited in the present disclosure.

In the exemplary embodiment, the wafer 40 includes a plurality of first cell groups S1, a plurality of second cell groups S2, a plurality of third cell groups S3 and a plurality of fourth cell groups S4. Each of the first cell groups S1, the plurality of second cell groups S2, the plurality of third cell groups S3 and the plurality of fourth cell groups S4 may include one or more cells. In one embodiment, the plurality of first cell groups S form the first upper bridge-arm switch Q1 of the first bridge arm, the plurality of second cell groups S2 form the second upper bridge-arm switch Q2 of the second bridge arm, the plurality of third cell groups S3 form the first lower bridge-arm switch Q3 of the first bridge arm, and the plurality of fourth cell groups S4 form the second lower bridge-arm switch Q4 of the second bridge arm.

In an exemplary embodiment, the above interleaved parallel circuit 200, 300 or 400 also includes a first inductor L1 and a second inductor L2. A first terminal of the first inductor L1 is electrically connected to the second terminal of the first upper bridge-arm switch Q1 and the first terminal of the first lower bridge-arm switch Q3. A first terminal of the second inductor L2 is electrically connected to the second terminal of the second upper bridge-arm switch Q2 and the first terminal of the second lower bridge-arm switch Q4. A second terminal of the first inductor L is electrically connected to a second terminal of the second inductor L2.

In another embodiment, still referring to FIGS. 4-6, there is also disclosed an integrated power module, which is applied in any of the above interleaved parallel circuits as shown in FIGS. 4-6. The integrated power module includes at least part of a first bridge arm and a second bridge arm. The first bridge arm includes a first upper bridge-arm switch Q1 and a first lower bridge-arm switch Q3. The first bridge arm also includes a first electrode PVIN electrically connected to a first terminal 11 of the first upper bridge-arm switch Q1, a second electrode GND electrically connected to a second terminal 32 of the first lower bridge-arm switch Q3, and a third electrode SW1 electrically connected to a second terminal 12 of the first upper bridge-arm switch Q1 and a first terminal 31 of the first lower bridge-arm switch Q3. The second bridge includes a second upper bridge-arm switch Q2 and a second lower bridge-arm switch Q4. The first electrode PVIN is electrically connected to a first terminal 21 of the second upper bridge-arm switch Q2. The second electrode GND is electrically connected to a second terminal 42 of the second lower bridge-arm switch Q4. The second bridge arm also includes a fourth electrode SW2 electrically connected to a second terminal 22 of the second upper bridge-arm switch Q2 and a first terminal 41 of the second lower bridge-arm switch Q4. The integrated power module also includes a first inductor L1 and a second inductor L2. A first terminal of the first inductor L1 is electrically connected to the third electrode SW1. A first terminal of the second inductor L2 is electrically connected to the fourth electrode SW2. A second terminal of the first inductor L1 is electrically connected to a second terminal of the second inductor L2. In FIG. 4, the first upper bridge-arm switch Q1 of the first bridge arm and the second upper bridge-arm switch Q2 of the second bridge arm are formed in a wafer 20. In FIG. 5, the first lower bridge-arm switch Q3 of the first bridge arm and the second lower bridge-arm switch Q4 of the second bridge arm are formed in a wafer 30. In FIG. 6, the first upper bridge-arm switch Q1 and the first lower bridge-arm switch Q3 of the first bridge arm, and the second upper bridge-arm switch Q2 and the second lower bridge-arm switch Q4 of the second bridge arm are formed in a wafer 40. The structure of the wafers 20, 30 and 40 are described as above, which will not be repeated herein.

In another embodiment, still referring to FIGS. 4 and 5, there is also disclosed an integrated power chip which is applied in a power circuit. The power circuit includes a first bridge arm and a second bridge arm, the structure and configuration of which may be the same as those of the first bridge arm and the second bridge arm in the above embodiments. The integrated power chip includes a first switch and a second switch. The first switch and the second switch are formed in a wafer. A plurality of first cell groups S1 and a plurality of second cell groups S2 are disposed on the wafer. As shown in FIG. 4, the plurality of first cell groups S1 are configured to form the first switch which is used as the first upper bridge-arm switch Q1 of the first bridge arm. The plurality of second cell groups S2 are configured to form the second switch which is used as the second upper bridge-arm switch Q2 of the second bridge arm. As shown in FIG. 5, the plurality of first cell groups S1 are configured to form the first switch which is used as the first lower bridge-arm switch Q3 of the first bridge arm. The plurality of second cell groups S2 are configured to form the second switch which is used as the second lower bridge-arm switch Q4 of the second bridge arm. The plurality of first cell groups S1 and the plurality of second cell groups S2 are switched on and off in an interleaved mode.

Hereinafter, the interleaved parallel circuit will be described in detail, taking the circuit as shown in FIG. 4 as an example.

In design of a chip, each power chip may be divided into numerous minimum functional units. The minimum functional units (referred to as cells in the present disclosure) may be connected to one another in parallel through conductive paths, to collectively form a semiconductor power device with current conduction capability. By controlling the area of the chip, and thus controlling the number of the cells integrated in the chip, the power capacity (i.e. the current conduction capability) of the chip may be determined.

In the interleaved parallel circuit provided by the embodiments of the present disclosure, which is operated in successive phases within the chip, it may be not required that all of the cells in the power chip are connected in parallel. Instead, the cells in the power chip are divided into a number m (m≧2) of groups. Cells in each group are connected in parallel, and controlled by the same control terminal to be switched on and off simultaneously. Cells in different groups are controlled by different control terminals, and are operated in different phases (the range of the phases may be for example 0˜180°). Here, the cells are divided into groups of the number m which corresponds to the number of the switches integrated in the wafer. For example, when an interleaved parallel circuit includes a number n of parallel bridge arms, and the upper bridge-arm switches or the lower bridge-arm switches of the n parallel bridge arms are integrated in the same wafer, m is equal to n and the m groups of cells are configured to respectively form the n upper bridge-arm switches or the n lower bridge-arm switches. Alternatively, when all of the upper bridge-arm switches and the lower bridge-arm switches of the n parallel bridge arms are integrated in the same wafer, the cells in the power chip may be divided into a number 2n of groups, meaning m=2n. The 2n groups of cells are configured to respectively form the n upper bridge-arm switches and the n lower bridge-arm switches. Alternatively, from any number k of the n parallel bridge arms in the interleaved parallel circuit, the upper bridge-arm switches and/or lower bridge-arm switches of the k parallel bridge arms may be integrated in the same wafer. Here, m and n each is a positive integer.

In an exemplary embodiment, the plurality of first cell groups S1 and the plurality of second cell groups S2 are switched on and off in an interleaved mode. In one embodiment, the plurality of first cell groups S and the plurality of second cell groups S2 may be switched on and off in an interleaved mode with a phase difference of 180 degrees. In another embodiment, the plurality of first cell groups S1 and the plurality of second cell groups S2 may be switched on and off in an interleaved mode with a phase difference of 120 degrees. In another embodiment, the plurality of first cell groups S1 and the plurality of second cell groups S2 may be switched on and off in an interleaved mode with a phase difference of 90 degrees. As an example, the interleaved mode with a phase difference of 180 degrees will be described in detail below.

Based on FIG. 4, the current conduction in metal layers of the power chip will be analyzed. Adjacent cell groups between two PVIN PADs (metal pads) will be described as an example. As shown in FIGS. 9(a), 9(b), 10(a) and 10(b), a first cell group S1 and a second cell group S2 are disposed adjacent to each other, respectively represented by a dash-line box. A first metal layer M1 is interconnection metal inside the chip, and configured to interconnect different cell groups. The impedance of the metal interconnection between the first cell group S1 and the second cell group S2 is r. The impedance of the path leading outside to the first electrode PVIN at the input side is R. Since the distance between the two groups of cells are generally far less than the distance between one group of cells and the PVIN PAD, it can be presumed that r<<R and r may be negligible.

As shown in FIGS. 9(a) and 9(b), when the power chip is not operated in successive phases, the first cell group S1 and the second cell group S2 are switched on simultaneously (as shown in FIG. 9(a)), or switched off simultaneously (as shown in FIG. 9(b)). In this case, the conduction loss of the first metal layer M1 in one cycle may be calculated through the following formula:

(2i)²×(R/2)×D=2i ² R×D  (3)

As shown in FIGS. 10(a) and 10(b), when the power chip is operated in successive phases, the first cell group S1 and the second cell group S2 are independently controlled to be switched on and off in an interleaved mode. In this case, the conduction loss of the first metal layer M1 in one cycle may be calculated through the following formula:

i ²×(R/2)×D+i ²×(R/2)×D=i ² R×D  (4)

Compared with the above formulas (3) and (4), it can be seen that by implementing an interleaved parallel circuit inside the power chip, it can more fully improve the utilization of the metal interconnection layer in the chip, and reduce the overall conduction loss, and in turn, reduce the overall loss of the chip.

In addition to the metal interconnection layer inside the chip (i.e. the above first metal layer M1), surface metal for packaging the chip will also cause conduction loss. Such conduction loss will be influenced by the position of the packaged pin (the position where the pin leads out), distribution of the cell groups operated in successive phases, and other factors. Therefore, more cells need to be analyzed. As discussed above, the cells inside the power chip which are operated in successive phases are divided into S1 and S2, and in each group, more cells are connected in parallel.

As shown in FIGS. 11-16, it may be assumed that a plurality of first cell groups S1 and a plurality of second cell groups S2 are disposed inside one power chip. It should be noted that, although in the figure only two first cell groups S1 and two second cell groups S2 are shown for illustration, in practice, the number of the first cell groups S and the second cell groups S2 are not limited. Moreover, the cells may not only be divided into two cell groups, but there may be a third cell group, a fourth cell group, . . . , a m^(th) cell group, where m is a positive integer. The m cell groups are switched on and off in successive phases, and adjacent two cell groups have phase difference of 2π/m, the cell groups of the same ordinal number are switched simultaneously. For example, the plurality of first cell groups S1 are switched on and off simultaneously, the plurality of second cell groups S2 are switched on and off simultaneously, and the first cell groups S1 and the second cell groups S2 are operated in successive phases.

In an exemplary embodiment, the plurality of first cell groups S1 have a plurality of first external pins. The plurality of second cell groups S2 have a plurality of second external pins. The geometric center of the plurality of first external pins of the first cell groups may be overlapped with the geometric center of the plurality of second external pins of the second cell groups. The cells are connected to a second metal layer M2 through surface PADs, that is, the package of the surface pads are connected to the metal layer. It may be assumed that the impedance of the interconnect metal of the package metal between the PADs is R0.

As shown in FIGS. 11(a) and 11(b), the external pin of the power chip operated in successive phases is near an edge (for example, the leftmost side) of the power chip and the two cell groups S1 and S2 are respectively distributed in two regions of the power chip. For example, two first cell groups S1 are disposed on the left side of the power chip, and two second cell groups S2 are disposed on the right side of the power chip. In FIG. 11(a), the two first cell groups S1 are simultaneously switched on, and the two second cell groups S2 are simultaneously switched off. In FIG. 11(b), the two first cell groups S1 are simultaneously switched off, and the two second cell groups S2 are simultaneously switched on. In FIGS. 11(a) and 11(b), the external pin p is disposed at the first one of the two first cell groups S1.

As shown in FIGS. 12(a) and 12(b), the external pin of the power chip operated in successive phases is near the central position of the power chip and the two cell groups S1 and S2 are respectively distributed in two regions of the power chip. The FIGS. 12(a) and 12(b) differ from the FIGS. 11(a) and 11(b) in that, the external pin p is disposed at the second one of the two first cell groups S1.

As shown in FIGS. 13(a) and 13(b), the external pin of the power chip operated in successive phases is near an edge of the power chip and the two cell groups S1 and S2 are arranged alternatively. For example, a first one of the second cell groups S2 is disposed between a first one of the first cell groups S1 and a second one of the first cell groups S1, and a second one of the first cell groups S1 is disposed between the first one of the second cell groups S2 and the second one of the second cell groups S2. The plurality of first cell groups S1 and the plurality of second cell groups S2 may be arranged similarly. The external pin p is disposed at the first one of the second cell groups S2.

As shown in FIGS. 14(a) and 14(b), the external pin of the power chip operated in successive phases is near the central position of the power chip and the two cell groups S1 and S2 are arranged alternatively. The FIGS. 14(a) and 14(b) differ from the FIGS. 13(a) and 13(b) in that the external pin p is disposed at the second one of the second cell groups S2.

As shown in FIG. 15, the external pin of the power chip operated in the same phase is near an edge of the power chip. The plurality of first cell groups S1 and the plurality of second cell groups S2 are simultaneously switched on and off. The external pin p is disposed at the first one of the first cell groups S1.

As shown in FIG. 16, the external pin of the power chip operated in the same phase is near the central position of the power chip. FIG. 16 differs from FIG. 15 in that the external pin p is disposed at the second one of the first cell groups S1.

The losses of the second metal layer M2 in one cycle respectively in the above embodiments are compared as shown in the following Table 1.

TABLE 1 FIGS. 11(a) FIG. 12(a) FIG. 13(a) FIG. 14(a) and 11(b) and 12(b) and 13(b) and 14(b) FIG. 15 FIG. 16 10i² 6i² 8i² 4i² 10i² 15i² R0 × D R0 × D R0 × D R0 × D R0 × D R0 × D

It can be seen that, regardless whether the position of the pin is near the central position or near the edge position (that is, whether the position of the pin is symmetric or not), the power chip operated in successive phases is advantageous in reducing the loss of the package metal layer. In order to maximize the utilization of the metal, it is preferred to dispose the pin of the power chip operated in successive phase or the position of the metal PAD near the center of the power chip. That is, for the interleaved parallel chip, symmetric pin position will be more desirable. Moreover, it may be more advantageous for improving the utilization of the metal layer that the first cell group S1 and the second cell group S2 which are operated in successive phases are arranged alternatively, compared arranging the first cell group S1 and the second cell group S2 in respective regions.

In the embodiments of the present disclosure, the symmetric position of the pin means that for the power chip operated in successive phases, the geometric center of all of the pins with the same reference (such as PVIN) or the geometric center of all of the metal PADs with the same reference is overlapping with the geometric center of the surface of the chip. Alternatively, it means that the distance between the geometric center of all of the pins with the same reference and the geometric center of the surface of the chip is less than half of the width of the chip. For the power chip operated in successive phases according to the embodiments of the present disclosure, arranged alternatively means that the cells in different cell groups in the power chip operated in successive phases are arranged alternatively, that is, the geometric center of all of the first cell groups S1 is overlapped with the geometric center of all of the second cell groups S2 (even overlapped with the geometric center of all of more cell groups Sn). Alternatively, a distance between the geometric centers of cell groups of any two ordinal numbers is less than half of the width of the chip.

The leading out position of the package pin or the position of the metal PAD on the surface of the chip is required to be defined at the central position of the chip based on the above discussion. The distribution of the external pin of the power chip operated in successive phases of FIG. 4 may be shown in FIG. 17. The first electrode PVIN is led out at the central position of the power chip, and the geometric center of the first electrode PVIN is overlapped with the geometric center of surface of the chip. In FIG. 17, a reference number 50 represents an edge of the power chip. As shown in FIG. 18, different pins are evenly distributed on the surface of the chip. The geometric center of all of the pins is closer to the central position of the surface of the chip, thereby improving the utilization of the metal of the pins in the whole and reducing metal conduction loss for the package of the chip. In FIG. 18, a reference number 60 represents an edge of the power chip.

In a practical design of the power chip operated in successive phases, in addition to the design of defining one power chip as a plurality of upper bridge-arm switches Q1 and Q2 as shown in FIG. 4, one power chip may also be defined as a plurality of lower bridge-arm switches Q3 and Q4, and may even be defined as a plurality of upper bridge-arm switches Q1 and Q2 and a plurality of lower bridge-arm switches Q3 and Q4. The above discussed design method and principle are all applicable. As shown in FIG. 19, Q1, Q2, Q3 and Q4 are defined in the same power chip operated in successive phases. The power chip requires more different pins. However, the pins are still arranged symmetrically to the center. In FIG. 19, a reference number 70 represents an edge of the power chip.

FIG. 20 schematically shows a second distribution of the external pins of the power chip operated in successive phases as shown in FIG. 6. FIG. 21 schematically shows a third distribution of the external pins of the power chip operated in successive phases as shown in FIG. 6. In FIGS. 20 and 21, the shapes of the electrodes are shown in hexagons for example. Along a particular direction of a hexagon, the first electrode PVIN and the second electrode GND are distributed alternatively and the third electrode SW1 and the fourth electrode SW2 are distributed alternatively.

As discussed above, in addition to improving the utilization of the metal layer of the chip itself, since the chip is operated in successive phases in this fundamental structure, the conduction loss by the package metal, the pin metal of the device and the metal of the system board apart from the chip could also benefit from near-continuously conducted current. Therefore, by designing a fundamental structure of the chip that operates in successive phases, utilization of the metal interconnection resources at the overall system level may be directly improved.

FIGS. 22-24 illustrate different distribution of the chip.

In an exemplary embodiment, a plurality of first cell groups S1 are disposed in a first region of a wafer 20, and a plurality of second cell groups S2 are disposed in a second region of a wafer 20.

As shown in FIG. 22, two cell groups S1 and S2 inside a power chip are respectively disposed in a first region and a second region. In FIG. 22, a reference number 80 represents an edge of the power chip.

As shown in FIG. 23, different cell groups are arranged alternatively in lateral direction, and disposed in parallel. The first region includes a plurality of first sub-regions, and the second region includes a plurality of second sub-regions. Each of the first sub-regions and the second sub-regions is in a strip shape. The plurality of first sub-regions and the plurality of second sub-regions are arranged alternatively and disposed in parallel. The cells on the wafer are disposed in different regions, and each sub-electrode leading out of each cell has a shape corresponding to the shape of a respective region. In FIG. 23, a reference number 90 represents an edge of the power chip.

As shown in FIG. 24, different cell groups are distributed alternatively and each of the cell groups is in a polygon. In this case, the cell groups on the chip operated in successive phases are arranged alternatively not only in the lateral direction but also in other directions. The first region includes a plurality of first sub-regions, and the second region includes a plurality of second sub-regions. Each of the first sub-regions and the second sub-regions is in a polygon shape. The plurality of first sub-regions and the plurality of second sub-regions are arranged alternatively. Although FIG. 24 only shows cell groups each in a quadrilateral shape, in practice, the shape of the cell group may be any polygon, such as pentagon, hexagon, and so on. In FIG. 24, a reference number 100 represents an edge of the power chip.

The above integrated power chip operated in successive phases may be applied to almost any existing circuit topology which allows operation in successive phases, such as any of a BUCK circuit, a BOOST circuit or a Totem-Pole circuit.

FIG. 25 schematically illustrates a BUCK circuit in which an interleaved parallel circuit according to the embodiments of the present disclosure is applied. The BUCK circuit, i.e. buck chopper circuit is one of a basic DC-DC circuit, generally used for DC to DC step-down conversion. The BUCK circuit is a single-tube non-isolated DC to DC converter with an output voltage lower than the input voltage, also known as a buck converter.

As shown in FIG. 25, the BUCK circuit includes a first bridge arm and a second bridge arm which are switched on in successive phases and connected in parallel. The first bridge arm includes a first upper bridge-arm switch Q1 and a first lower bridge-arm switch Q2. The second bridge arm includes a second upper bridge-arm switch Q3 and a second lower bridge-arm switch Q4. A first terminal of the first upper bridge-arm switch Q1 of the first bridge arm and a first terminal of the second upper bridge-arm switch Q3 of the second bridge arm are electrically connected to a power source V_(IN). A second terminal of the first lower bridge-arm switch Q2 of the first bridge arm and a second terminal of the second lower bridge-arm switch Q4 of the second bridge arm are electrically connected to ground. The BUCK circuit also includes stray parameters Z1 and Z2. In an embodiment, the BUCK circuit also includes a first inductor L1 and a second inductor L2. The first inductor L1 is electrically connected to a second terminal of the first upper bridge-arm switch Q1 and a first terminal of the first lower bridge-arm switch Q2. The second inductor L2 is electrically connected to a second terminal of the second upper bridge-arm switch Q3 and a first terminal of the second lower bridge-arm switch Q4. A second terminal of the first inductor L1 and a second terminal of the second inductor L2 are electrically connected to a load capacitor C_(O). In the embodiment, Q1-Q4 are switch tubes generally driven by a Pulse Width Modulation (PWM) signal.

FIG. 26 schematically illustrates a BOOST circuit in which an interleaved parallel circuit according to the embodiments of the present disclosure is applied. The BOOST circuit is a DC to DC converter with an output voltage higher than the input voltage, also known as a boost converter.

As shown in FIG. 26, the BOOST circuit includes a first bridge arm and a second bridge arm which are switched on in successive phases and connected in parallel. The first bridge arm includes a first upper bridge-arm switch Q1 and a first lower bridge-arm switch Q2. The second bridge arm includes a second upper bridge-arm switch Q3 and a second lower bridge-arm switch Q4. A second terminal of the first upper bridge-arm switch Q1 of the first bridge arm and a first terminal of the first lower bridge-arm switch Q2 of the first bridge arm are electrically connected to a power source Vm through a first inductor L1. A second terminal of the second upper bridge-arm switch Q3 of the second bridge arm and a first terminal of the second lower bridge-arm switch Q4 of the second bridge arm are electrically connected to the power source Vm through a second inductor L2. A second terminal of the first lower bridge-arm switch Q2 of the first bridge arm and a second terminal of the second lower bridge-arm switch Q4 of the second bridge arm are connected to ground. The BOOST circuit also includes stray parameters Z1 and Z2. The first terminal of the first upper bridge-arm switch Q1 and the first terminal of the second upper bridge-arm switch Q3 are electrically connected to a first terminal of a load capacitor C_(O) through the stray parameter Z1. The second terminal of the first lower bridge-arm switch Q2 and the second terminal of the second lower bridge-arm switch Q4 are electrically connected to a second terminal of the load capacitor C_(O) through the stray parameter Z2. In the embodiment, Q1-Q4 are switch tubes generally driven by a Pulse Width Modulation (PWM) signal. The duty cycle of Q1-Q4 is restricted to less than 1, and they are not allowed to operate with a duty cycle of 1. The first inductor L1 and the second inductor L2 are at the input side and referred to as boost inductors.

FIG. 27 schematically illustrates a Totem-Pole circuit in which an interleaved parallel circuit according to the embodiments of the present disclosure is applied.

As shown in FIG. 27, the Totem-Pole circuit includes a first bridge arm and a second bridge arm which are switched on in successive phases and connected in parallel. The first bridge arm includes a first upper bridge-arm switch Q1 and a first lower bridge-arm switch Q2. The second bridge arm includes a second upper bridge-arm switch Q3 and a second lower bridge-arm switch Q4. A second terminal of the first upper bridge-arm switch Q1 of the first bridge arm and a first terminal of the first lower bridge-arm switch Q2 of the first bridge arm are electrically connected to a first terminal of a power source V_(IN) through a first inductor L1. A second terminal of the second upper bridge-arm switch Q3 of the second bridge arm and a first terminal of the second lower bridge-arm switch Q4 of the second bridge arm are electrically connected to the first terminal of the power source V_(IN) through a second inductor L2. A second terminal of the first lower bridge-arm switch Q2 of the first bridge arm and a second terminal of the second lower bridge-arm switch Q4 of the second bridge arm are connected to ground. The Totem-Pole circuit also includes a first diode D1 and a second diode D2 connected in series. The branch of the first diode D1 and the second diode D2 is connected to the first bridge arm and the second bridge arm in parallel. The anode of the first diode D1 is electrically connected to the cathode of the second diode D2. The cathode of the first diode D1 is electrically connected to a first terminal of the first bridge arm and the second bridge arm. The second terminal of the second diode D2 is connected to ground. In the embodiment, the anode of the first diode D1 and the cathode of the second diode D2 are electrically connected to a second terminal of the power source V_(IN). The Totem-Pole circuit also includes stray parameters Z1 and Z2. The first terminal of the first upper bridge-arm switch Q1 and the first terminal of the second upper bridge-arm switch Q3 are electrically connected to a first terminal of a load capacitor C_(O) through the parameter Z1. The second terminal of the first lower bridge-arm switch Q2 and the second terminal of the second lower bridge-arm switch Q4 are electrically connected to a second terminal of the load capacitor C_(O) through the parameter Z2.

Accordingly, in the interleaved parallel circuit, integrated power module and the integrated power chip of the present disclosure, by defining and designing an integrated chip operated in successive phases, and disposing a plurality of half bridges inside a single power chip, utilization of the interconnection conduction paths such as the metal layers, the package and the system board inside the chip can be significantly improved when the power chip is operated in successive phases, and the unevenness of theses metal conductors due to the switch operation mode can be effectively reduced. The loss of the conduction paths can be significantly reduced and it facilitates reducing the volume of the power module which contains the chip and improving its efficiency.

Other embodiments of the invention will be apparent to those skilled in the art from consideration of the specification and practice of the invention disclosed here. This application is intended to cover any variations, uses, or adaptations of the invention following the general principles thereof and including such departures from the present disclosure as come within known or customary practice in the art. It is intended that the specification and examples be considered as exemplary only, with a true scope and spirit of the invention being indicated by the following claims. 

What is claimed is:
 1. An interleaved parallel circuit comprising a first bridge arm and a second bridge arm, wherein the first bridge arm comprises: a first upper bridge-arm switch comprising a first terminal, a second terminal and a control terminal; and a first lower bridge-arm switch comprising a first terminal, a second terminal and a control terminal; wherein the second terminal of the first upper bridge-arm switch is electrically connected to the first terminal of the first lower bridge-arm switch; the second bridge arm comprises: a second upper bridge-arm switch comprising a first terminal, a second terminal and a control terminal; and a second lower bridge-arm switch comprising a first terminal, a second terminal and a control terminal; wherein the second terminal of the second upper bridge-arm switch is electrically connected to the first terminal of the second lower bridge-arm switch; wherein the first bridge arm and the second bridge arm are at least partly formed in a wafer containing a plurality of first cell groups and a plurality of second cell groups; wherein the plurality of first cell groups are configured to form the first upper bridge-arm switch of the first bridge arm and the plurality of second cell groups are configured to form the second upper bridge-arm switch of the second bridge arm, or the plurality of first cell groups are configured to form the first lower bridge-arm switch of the first bridge arm and the plurality of second cell groups are configured to form the second lower bridge-arm switch of the second bridge arm; and the plurality of first cell groups and the plurality of second cell groups are switched on and off in an interleaved mode.
 2. The interleaved parallel circuit according to claim 1, wherein the wafer is composed by the plurality of first cell groups and the plurality of second cell groups.
 3. The interleaved parallel circuit according to claim 1, further comprising: a first inductor comprising a first terminal and a second terminal, the first terminal of the first inductor being electrically connected to the second terminal of the first upper bridge-arm switch and the first terminal of the first lower bridge-arm switch; and a second inductor comprising a first terminal and a second terminal, the first terminal of the second inductor being electrically connected to the second terminal of the second upper bridge-arm switch and the first terminal of the second lower bridge-arm switch; wherein the second terminal of the first inductor is electrically connected to the second terminal of the second inductor.
 4. The interleaved parallel circuit according to claim 1, wherein the plurality of first cell groups and the plurality of second cell groups are switched on and off in the interleaved mode with a phase difference of 180 degrees, 120 degrees or 90 degrees.
 5. The interleaved parallel circuit according to claim 1, wherein the plurality of first cell groups have a plurality of first external pins, the plurality of second cell groups have a plurality of second external pins, a geometric center of the plurality of first external pins overlaps with a geometric center of the plurality of second external pins.
 6. The interleaved parallel circuit according to claim 1, wherein the plurality of first cell groups are disposed in a first region of the wafer, and the plurality of second cell groups are disposed in a second region of the wafer.
 7. The interleaved parallel circuit according to claim 6, wherein the first region contains a plurality of first sub-regions, and the second region contains a plurality of second sub-regions, each of the first sub-regions and the second sub-regions is in a stripe shape, and the first sub-regions and the second sub-regions are arranged alternatively in parallel.
 8. The interleaved parallel circuit according to claim 6, wherein the first region contains a plurality of first sub-regions, and the second region contains a plurality of second sub-regions, each of the first sub-regions and the second sub-regions is in a polygon shape, and the first sub-regions and the second sub-regions are arranged alternatively.
 9. The interleaved parallel circuit according to claim 1, wherein the interleaved parallel circuit is a BUCK circuit, a BOOST circuit or a Totem-Pole circuit.
 10. An integrated power module, which is applied in an interleaved parallel circuit comprising a first bridge arm and a second bridge arm, wherein the first bridge arm comprises: a first upper bridge-arm switch comprising a first terminal, a second terminal and a control terminal; and a first lower bridge-arm switch comprising a first terminal, a second terminal and a control terminal; a first electrode electrically connected to the first terminal of the first upper bridge-arm switch; a second electrode electrically connected to the second terminal of the first lower bridge-arm switch; and a third electrode electrically connected to the second terminal of the first upper bridge-arm switch and the first terminal of the first lower bridge-arm switch; the second bridge arm comprises: a second upper bridge-arm switch comprising a first terminal, a second terminal and a control terminal, the first electrode being electrically connected to the first terminal of the second upper bridge-arm switch; a second lower bridge-arm switch comprising a first terminal, a second terminal and a control terminal, the second electrode being electrically connected to the second terminal of the second lower bridge-arm switch; and a fourth electrode electrically connected to the second terminal of the second upper bridge-arm switch and the first terminal of the second lower bridge-arm switch; the integrated power module further comprises: a first inductor comprising a first terminal and a second terminal, the first terminal of the first inductor being electrically connected to the third electrode; and a second inductor comprising a first terminal and a second terminal, the first terminal of the second inductor being electrically connected to the fourth electrode; wherein the second terminal of the first inductor is electrically connected to the second terminal of the second inductor; the first upper bridge-arm switch of the first bridge arm and the second upper bridge-arm switch of the second bridge arm and/or the first lower bridge-arm switch of the first bridge arm and the second lower bridge-arm switch of the second bridge arm are formed in a wafer.
 11. The integrated power module according to claim 10, wherein the first upper bridge-arm switch of the first bridge arm and the second upper bridge-arm switch of the second bridge arm are formed in the wafer, the wafer contains a plurality of first cell groups and a plurality of second cell groups; wherein the plurality of first cell groups are configured to form the first upper bridge-arm switch of the first bridge arm, the plurality of second cell groups are configured to form the second upper bridge-arm switch of the second bridge arm; and the plurality of first cell groups and the plurality of second cell groups are switched on and off in an interleaved mode.
 12. The integrated power module according to claim 10, wherein the first lower bridge-arm switch of the first bridge arm and the second lower bridge-arm switch of the second bridge arm are formed in the wafer, the wafer contains a plurality of first cell groups and a plurality of second cell groups; wherein the plurality of first cell groups are configured to form the first lower bridge-arm switch of the first bridge arm, the plurality of second cell groups are configured to form the second lower bridge-arm switch of the second bridge arm; and the plurality of first cell groups and the plurality of second cell groups are switched on and off in an interleaved mode.
 13. The integrated power module according to claim 11, wherein the wafer is composed by the plurality of first cell groups and the plurality of second cell groups.
 14. The integrated power module according to claim 12, wherein the wafer is composed by the plurality of first cell groups and the plurality of second cell groups.
 15. An integrated power chip, which is applied in a power circuit comprising a first bridge arm and a second bridge arm, the first bridge arm comprising a first upper bridge-arm switch and a first lower bridge-arm switch, the second bridge arm comprising a second upper bridge-arm switch and a second lower bridge-arm switch, wherein the integrated power chip comprises a first switch and a second switch, the first switch and second switch are formed in a wafer, and the wafer contains a plurality of first cell groups and a plurality of second cell groups; wherein the plurality of first cell groups are configured to form the first switch as the first upper bridge-arm switch of the first bridge arm and the plurality of second cell groups are configured to form the second switch as the second upper bridge-arm switch of the second bridge arm, or the plurality of first cell groups are configured to form the first switch as the first lower bridge-arm switch of the first bridge arm and the plurality of second cell groups are configured to form the second switch as the second lower bridge-arm switch of the second bridge arm; and the plurality of first cell groups and the plurality of second cell groups are switched on and off in an interleaved mode.
 16. The integrated power chip according to claim 15, wherein the wafer is composed by the plurality of first cell groups and the plurality of second cell groups. 